Device for producing and filling container products

ABSTRACT

1 . Device for producing and filling container products
           2 . A device for producing and filling container products, in which at least one hose ( 19 ) of plasticized plastic material can be extruded into an opened mold ( 7 ) starting from an extrusion head ( 13 ) along a hose guide, wherein by means of at least one filling mandrel ( 1 ), which at least in one functional position extends through the extrusion head ( 13 ), a filling material can be introduced into the relevant container and wherein at least one process gas feeder device ( 21, 23 ) can be used to bring a process gas into the interior of the hose ( 19 ), wherein the process gas feeder device ( 21, 23 ) has a guide duct ( 21 ) extending inside the extrusion head ( 13 ) along the outside of the filling mandrel ( 1 ), is characterized in that at least part of the process gas introduced is discharged through the extrusion head ( 13 ) along at least one predeterminable exhaust gas duct ( 35 ), which is separated from the relevant guide duct ( 21 ).

The invention relates to a device for producing and filling container products having the features in the preamble of claim 1.

Devices of this type are state of the art. Document WO 2009/152979 discloses a device operating in accordance with the well-known Bottelpack® system, which permits automated forming (blowing or vacuum forming), filling and closing of containers in an economical way. If sensitive products, for instance pharmaceuticals, are to be filled into the above-mentioned containers, the international standards for aseptic packaging must be met. In order to meet these requirements, the process gas used as supporting air, which is introduced into the interior of the hose to stabilize the guide of the free hose section between the extrusion head and the mold, is sterile air, such that a so-called sterile filling chamber (ASR) is formed, in which the sterile air forms an effective protection against the penetration of germs, until after completion of the filling process, moving mold parts of the mold are closed to form the desired head closure of the container using a combined vacuum welding process.

DE 1 479 698 describes a device for producing and filling container products having the features in the preamble of claim 1, in which at least one hose of plasticized plastic material can be extruded into an opened mold starting from an extrusion head along a hose guide, wherein by means of at least one filling mandrel, which extends through the extrusion head in at least one functional position, a filling material can be introduced into the relevant container and wherein at least one process gas feeder device can be used to bring process gas into the interior of the hose, wherein the process gas feeder device within the extrusion head has a guide duct extending along the outside of the filling mandrel.

A further device of this type is shown in DE 1 180 301.

Based on this state of the art, the invention addresses the problem of providing an advantageous device of the aforementioned type, which can be used in a particularly safe and economical manner for the manufacture of containers for pharmaceutical or diagnostic purposes and which, in accordance with the official regulations, permits an at least partially continuous and representative measurement of the required clean room class of the hose interior near a filling position.

According to the invention, this problem is solved by a device having the features of claim 1 in its entirety.

According to the characterizing part of claim 1, an essential characteristic of the invention is that at least part of the additionally introduced process gas is discharged through the extrusion head starting from the interior of the hose along at least one predeterminable exhaust gas duct, which is separated from the relevant process gas feed. This means that, without having to interrupt the manufacturing process of the device, a quantity of test gas originating from the space inside the hose is available via the exhaust gas duct, which can be analyzed, for instance, to prove compliance with the specifications regarding clean-room class, residual oxygen content or the like. Sterile air or—for instance for oxygen-sensitive products—an inert gas such as nitrogen or argon can be used as a process gas.

The presence of the exhaust gas duct provides the option of providing at least one further device feeding process gas, by means of which additional process gas can be brought into the interior of the hose, preferably close to the inner surface of the hose, via at least one further process gas feed. In this way a substantially increased quantity of gas can be introduced into the hose—compared to just the supporting air according to the state of the art—and thus a particularly effective regulation for stabilizing the hose forming and guide is feasible. In addition, the temperature of the process gas can be controlled to have a direct influence on the temperature of the inside of the hose. Furthermore, the flow profile inside the hose can be adjusted by selecting the flow rate and flow velocity of the process gas. If additional process gas is introduced, it is advantageous to have at least one additional exhaust gas duct, by means of which process gas can be discharged in addition to the analysis quantity.

The arrangement can be advantageously made such that at least in part the number of exhaust gas ducts used is greater than the number of process gas feeds by at least one increment.

Advantageously, a vacuum-generating device can be connected to at least one of the exhaust gas ducts, which vacuum-generating device permits the regulated extraction of process gas to an optimum extent for stabilizing the hose forming and guide, as well as supplying constant, regulated gas quantities to the gas analyzers, particle counters, etc.

In particularly advantageous exemplary embodiments, one process gas feed runs at least partially between the relevant filling mandrel and a support housing, in which the filling mandrel is guided in a longitudinally movable manner, wherein parts of this one process gas feed pass into branching functional ducts running in the support housing, which block the entry of potentially impure ambient air into the process gas feed and thus into the interior of the hose.

The arrangement can be advantageously made in such a way that at least one free end of one exhaust gas duct, which is provided for purposes of physical and/or chemical analysis, opens into a branch chamber in the extrusion head, which is penetrated by the filling pin and into which at least the process gas from the inside of the hose penetrates.

Preferably, one free end of the further process gas feed opens into the branch chamber on the side opposite from the side on which one of the exhaust gas ducts opens into the branch chamber. At least one further process gas feed can open laterally into the branch chamber.

In addition, at least one of the exhaust gas ducts may preferably be connected to the regulable, vacuum-generating device and open into the branch chamber laterally and in parallel to the one further process gas feed.

Advantageously at least one exhaust gas duct can open into the inside of the hose and can pass through the extrusion head in a duct-like manner and be arranged in parallel to the filling mandrel.

Below the invention is explained in detail with reference to exemplary embodiments shown in the drawing. In the Figures:

FIG. 1 shows a vertical section of a part of a device operating in accordance with the Bottelpack® system according to the state of the art, wherein only the area of the filling mandrels is shown, the filling needle-like ends of the only visible mandrel extend into a mold having movable mold parts;

FIG. 2 shows a representation corresponding to FIG. 1, wherein a first exemplary embodiment of the device according to the state of the art is shown; and

FIGS. 3 and 4 show corresponding representations of a second and a third exemplary embodiment of the device according to the invention.

FIG. 1 shows a device part of a known device for producing and filling container products by blow or vacuum forming, which essentially corresponds to the device part as shown in FIG. 5 of WO 2009/152 979 A1 mentioned in the state of the art. As in this figure, only one single filling mandrel 1 of a plurality of filling devices arranged in a row perpendicular to the drawing plane is visible, which filling mandrel is mounted in a support housing 3 in the manner customary for such devices to be moved in a controlled manner into various selected operating positions. FIG. 1 shows the visible filling mandrel 1 in an extended operating position for a filling process, wherein the filling-needle-like tapered end section 5 is extended into a form 7, which is not yet closed at the head end. In a kind of carousel arrangement, individual mold parts 9 are moved towards each other in pairs on a fictitious circular arc path 10 to form a closed manufacturing mold, and are moved apart again to open the mold. Every filling mandrel 1 has a centrally located filling duct 11 for a metered dosing of filling material from the end section 5. In the manner usual for such devices, the filling ducts 11 can be supplied with controlled dose units of the product to be filled from a central filling material pipe (not shown).

An extrusion head 13—often also referred to as a hose head—is mounted on the support housing 3, which has an annular extrusion nozzle 17 on its end face 15 in a manner known per se, from which a hose 19 emerges during operation, which is formed from plasticized plastic material, which is fed into the extrusion head 13 from an extruder device (not shown). Because such extruder devices and the design of the extrusion head 13, are known per se, for instance in the form of devices operating according to the Bottelpack® process, no further explanations of the details to this effect are required.

A so-called process gas feeder device or supporting air device is provided in the known manner to stabilize the free hose forming and guide along the hose 19 from the extrusion nozzle 17 into the form 7. It has a guide duct 21 extending inside the support housing 3 and the extrusion head 13 along the outside of the filling mandrel 1, which guide duct, starting from an inlet 23, which is located on a sleeve-like end part 25 of the support housing 3, extends along the outside of the relevant filling mandrel 1 to an outlet orifice 27 on the end face 15 of the extrusion head 13. Based on the inflow of sterile process gas or sterile supporting air into the interior of the hose 19 via the outlet opening 27, which along its course from the extrusion head 13 into the mold 7 forms a closed space 29, the interior of the hose forms the sterile filling space, inside which the entire production process is performed, i.e. up to the closing of the head of the filled container, which is performed by closing the relevant head jaws of the mold 7. As the corresponding mechanisms of the mold 7 are known per se, the drawing shows the mold designated as a whole by the numeral 7 merely as a simplified schematic, i.e. without a separate representation of main mold parts and head mold parts. To shield the guide duct 21 against the ingress of ambient air, the end part 25 of the support housing is provided with 3 transverse function ducts 31, which are connected to the guide duct 21 and through which supporting air or process gas can disperse freely. Additional free dispersing ducts 33 for process gas are provided at the outer end of the end part 25 of the support housing 3.

The gas chamber 29 within the hose 19 is not accessible for analytical purposes; in addition, the great length of the process gas feeding duct 21 and the low process gas or supporting air volume flows render a precise and reliable control of the hose design for production difficult.

FIGS. 2 to 4 show exemplary embodiments of the device according to the invention. These have additional short inlets and/or outlets for pure, sterile process gas and branch chambers in the extrusion head—and thus in close proximity to the inner wall of the hose. The first exemplary embodiment of FIG. 2 differs from the state of the art as shown in FIG. 1 in that, on the one hand, an exhaust gas duct 35 is additionally provided, which extends for a large part of its length in parallel to the filling mandrel 1 within the extrusion head 13 and the adjoining section 37 of the support housing 3, in that one exhaust gas outlet 39 exits from the section 37 and opens into a branch chamber 41 in the extrusion head 13 on the inlet side. On the other hand, the example of FIG. 2 differs from the state of the art by the presence of two further process gas feeds 43 and 45, which extend from the process gas inlets 42 and 44, respectively, in parallel to the filling mandrel 1, through the extrusion head 13 and open into the inner chamber 29 of the hose 19, closely adjacent to the extrusion nozzle 17. Based on a regulated introduction of the additional process gas flows, a representative quantity of gas from the chamber 29 penetrates into the branch chamber 41 and from there into the exhaust gas duct 35 and can thus be removed at its exhaust gas outlet 39. Thus, during operation of the device, a gas quantity (sample gas) having a representative composition is continuously available, which can be extracted for the analysis purposes, for instance, to prove that the device meets the required purity class, or—for instance for oxygen-sensitive filling goods—the residual oxygen concentration in the hose is sufficiently low. A suitable measuring device (not shown) for the purpose of physical and/or chemical analyses, for instance a particle counter, can be connected to the exhaust gas outlet 39.

FIG. 3 shows a second exemplary embodiment of the device according to the invention. It differs from the example in FIG. 2 in that two additional exhaust gas ducts 51 and 53 are provided, which, starting from an orifice 55 and 57 respectively, are located on the end face 15 of the extrusion head 13 closely adjacent to the extrusion nozzle 17 and extend in parallel to the filling mandrel 1 to the exhaust gas outlets 59 and 61, respectively, at the housing section 37. As in the example of FIG. 2, an additional process gas feed 43 is provided, which starts from the process gas inlet 42 and whose main part extends in the extrusion head 13 in parallel to the filling mandrel 1. A further difference, for instance from FIG. 2, is that the additional process gas duct 43 is not routed directly into the interior 29 in the hose 19, but opens into the branch chamber 41 on the side opposite from the side into which the exhaust gas duct 35 opens. One part of the sterile process gas passes from the branch chamber 41 into the interior 29 of the hose 19, while another part flows into the guide duct 21 and thus acts as a barrier against potential impurities from the parts of the device located above the branch chamber 41.

FIG. 4 shows a third exemplary embodiment of the device according to the invention. It differs from the example in FIG. 3 in that not only the one exhaust gas duct 35 and the additional process gas feed 43 open into the branch chamber 41, but that a further exhaust gas duct 71 opens into the branch chamber 41. Like the process gas duct 43, the main part of the additional exhaust gas duct 71 runs inside the extrusion head 13 in parallel to the filling mandrel 1 and exits at an exhaust gas outlet 73 in the housing section 37. A device generating negative pressure, which is not shown, is connected to the exhaust gas outlet 73, for the controlled extraction and thus the adjustment of a desired pressure level, at which in operation a quantity of sample gas is available for analysis at the exhaust gas outlet 39, while at the same time the additional process gas introduced provides for the stable guide of the hose 19 enclosing the chamber 29.

The designs in accordance with the invention also permit significantly higher gas flow rates compared to the supporting air used exclusively in the state of the art. In this way, the flow profile inside the hose 29 can be specifically adjusted. This is advantageous useable for the described analytical purposes, for efficiently rinsing the interior of the hose 29 or for fine-tuning the temperature of the inner hose surface. This is achieved by pre-heating/cooling the supplied sterile process gas and adjusting its flow rate and flow velocity and is important for the safe sealing of the filled containers by welding.

Due to the according to the invention increased gas flow rates, aerosols or explosive vapors of the filling material, which can occur during the filling process, for instance, can be reliably and directly removed and can be optionally detected and analyzed by a measuring instrument at the exhaust outlet 39.

Furthermore, the versions according to the invention permit a simultaneous and selective use of different and/or differently conditioned process gases. For instance, in products that can form explosive mixtures, only air can be supplied via the feed 21 and simultaneously an inert gas—optionally pre-tempered, such as nitrogen, carbon dioxide or argon, can be supplied via the feeds 43. This ensures explosion protection on the one hand and reduces the demand for inert gas on the other, resulting in lower production costs. 

1. A device for producing and filling container products, in which at least one hose (19) of plasticized plastic material can be extruded into an opened mold (7) starting from an extrusion head (13) along a hose guide, wherein by means of at least one filling mandrel (1), which at least in one functional position extends through the extrusion head (13), a filling material can be introduced into the relevant container and wherein at least one process gas feeder device (21, 23) can be used to bring a process gas into the interior of the hose (19), wherein the process gas feeder device (21, 23) has a guide duct (21) extending inside the extrusion head (13) along the outside of the filling mandrel (1), characterized in that at least part of the process gas introduced is discharged through the extrusion head (13) along at least one predeterminable exhaust gas duct (35), which is separated from the relevant guide duct (21).
 2. The device according to claim 1, characterized in that the process gas can be supplied pre-tempered.
 3. The device according to claim 1, characterized in that there is at least one further process gas feeder device, which can be used to bring additional process gas into the interior of the hose (19) via at least one further process gas feed (43), preferably close to the interior of the hose (29) at the point of exit from the extrusion head (13).
 4. The device according to claim 1, characterized in that different and/or differently conditioned process gases, preferably air and an inert gas, can be introduced at least partially simultaneously via the guide duct (21) and the process gas feed (43).
 5. The device according to claim 1, characterized in that at least one further exhaust gas duct (51, 53) is provided, by means of which the process gas can be at least partially discharged from the interior of the hose (19), preferably from the inside (29) thereof.
 6. The device according to claim 1, characterized in that at least in part the number of exhaust gas ducts (21, 35, 51, 53, 71) used is greater than the number of process gas feeds (43, 45) by at least one increment.
 7. The device according to claim 1, characterized in that a preferably controllable vacuum-generating device is connected to at least one (35, 71) of the exhaust gas ducts (35, 51, 53, 71).
 8. The device according to claim 1, characterized in that a measuring device, in particular for the purpose of physical and/or chemical analyses, can be connected to at least one (35) of the exhaust gas ducts (35, 51, 53, 71).
 9. The device according to claim 8, characterized in that the measuring device is a particle counting device.
 10. The device according to claim 1, characterized in that at least a partial flow of the process gas enters from a branch chamber (41) into the relevant guide duct (21), which runs at least partially between the relevant filling mandrel (1) and a support housing (3), in which the filling mandrel (1) is guided in a longitudinally displaceable manner, and exits via functional ducts (31), running in the support housing (3), and prevents the entry of ambient air by blocking.
 11. The device according to claim 1, characterized in that at least one end of one exhaust gas duct (35) opens into a branch chamber (41) in the extrusion head (13), through which the filling mandrel (1) extends and into which at least the process gas from the interior of the hose (19) penetrates.
 12. The device according to claim 1, characterized in that one end of the further process gas duct (43) opens into the branch chamber (41) on the side opposite from the side on which one of the exhaust gas ducts (35) opens into the branch chamber (41).
 13. The device according to claim 1, characterized in that the at least one further exhaust gas duct (71) opens laterally into the branch chamber (41).
 14. The device according to claim 1, characterized in that at least one (35, 71) of the exhaust gas ducts (35, 51, 53, 71) is preferably connected to the regulable, vacuum-generating device and opens into the branch chamber (41) laterally and in parallel to the one further process gas duct (43).
 15. The device according to claim 1, characterized in that at least one exhaust gas guide (51, 53) opens into the inside (29) of the hose (19) and passes through the extrusion head (13) in a duct-like manner and is arranged in parallel to the filling mandrels (1). 